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This book highlights progress towards the capture, storage, and utilization of energy through the development of advanced materials and systems based on abundant elements, materials, and commodities. Energy is critical to human sustainability and a global-scale deployment of renewable energy systems will be required. Hence, the chapters integrate the fundamental aspects that enable the technical advancements in detail, along with an emphasis on the need for highly sustainable materials to enable real impact for humankind: To determine innovation of energy capture and storage through characterizations of materials in areas of electrical generation and electrical storage systems; To demonstrate better performance, economic and environmental advantages than the current state of the art; To define new chemistries and materials for innovations in energy density design through lower operational temperatures, improve safety, expanding operational voltage, battery durability lifetimes, and reduce system costs. Advances critical technical and commercial objectives for novel high energy density materials; Evaluates operational material models for optimizing energy capture that are integrated by configurations as a system; Illustrates utilization of material life cycle assessment for high energy outputs generators for sustainable materials.
This book highlights progress towards the capture, storage, and utilization of energy through the development of advanced materials and systems based on abundant elements, materials, and commodities. Energy is critical to human sustainability and a global-scale deployment of renewable energy systems will be required. Hence, the chapters integrate the fundamental aspects that enable the technical advancements in detail, along with an emphasis on the need for highly sustainable materials to enable real impact for humankind: To determine innovation of energy capture and storage through characterizations of materials in areas of electrical generation and electrical storage systems; To demonstrate better performance, economic and environmental advantages than the current state of the art; To define new chemistries and materials for innovations in energy density design through lower operational temperatures, improve safety, expanding operational voltage, battery durability lifetimes, and reduce system costs. Advances critical technical and commercial objectives for novel high energy density materials; Evaluates operational material models for optimizing energy capture that are integrated by configurations as a system; Illustrates utilization of material life cycle assessment for high energy outputs generators for sustainable materials.
The search for cleaner, cheaper, smaller and more efficient energy technologies has to a large extent been motivated by the development of new materials. The aim of this collection of articles is therefore to focus on what materials-based solutions can offer and show how the rationale design and improvement of their physical and chemical properties can lead to energy-production alternatives that have the potential to compete with existing technologies. In terms of alternative means to generate electricity that utilize renewable energy sources, the most dramatic breakthroughs for both mobile (i.e., transportation) and stationary applications are taking place in the fields of solar and fuel cells. And from an energy-storage perspective, exciting developments can be seen emerging from the fields of rechargeable batteries and hydrogen storage.
Sustainable development is a very prevalent concept of modern society. This concept has appeared as a critical force in combining a special focus on development and growth by maintaining a balance of using human resources and the ecosystem in which we are living. The development of new and advanced materials is one of the powerful examples in establishing this concept. Green and sustainable advanced materials are the newly synthesized material or existing modified material having superior and special properties. These fulfil today’s growing demand for equipment, machines and devices with better quality for an extensive range of applications in various sectors such as paper, biomedical, textile, and much more. Volume 2, provides chapters on the valorization of green and sustainable advanced materials from a biomedical perspective as well as the applications in textile technology, optoelectronics, energy materials systems, and the food and agriculture industry.
2016 International Conference on Advanced Materials and Energy Sustainability [AMES2016] was held in Wuhan, Hubei, China during May 27-29, 2016. AMES2016 aims to bring together researchers, engineers, and students to participate in the discussion of Advanced Materials and Energy Sustainability. AMES2016 features unique mixed topics of Advanced Materials and Related Technology, Energy Management and Renewable Energy and Environmental Engineering and Sustainable Development.The conference program committee is greatly honoured to have three renowned experts for taking time off to present their keynotes to the conference. In addition, we have put together five invited sessions. There are a total of 260 submissions from various parts of the world. Among them, 87 articles are compiled into this proceedings, covering Polymers, Composites and Mesoporous Materials; Applications of Micro- and Nano-Technology and Materials; Processing Technologies and Computational Methods in Area of Materials Science; Smart Grid, Micro-Grid Concepts; Fuels, Combustion and Materials Handling; Advanced and Renewable Energy Systems; Sustainable Management of Environment; Sustainable Cities and Communities, Transportation and Wind Energy Systems and Technologies.
Industry 4.0 is revolutionizing the way companies manufacture, improve, and distribute their products. It demands the application of renewable energy using advanced materials. Renewable energy is reshaping the fields of industry, agriculture, and households, providing reliable power supplies and fuel diversification. This enhances energy security, lowers the risk of fuel spills, and reduces the need for imported fuels. Examples of material applications used for renewable energy are photovoltaic, solar cells, which can be used in agriculture. This volume has a diverse audience including students, researchers, and academics engaged in materials and renewable energy. Features : Presents latest research on renewable energy in relation to urbanization, industrialization, and the environment. Provides in-depth discussion on modeling and simulation using latest techniques. Provides technical exposure for the readers on advanced materials. Provides numerous examples on properties of biomaterials and their future prospect. Provides up-to-date information on functional materials for industrial application.
Electrochemical Energy: Advanced Materials and Technologies covers the development of advanced materials and technologies for electrochemical energy conversion and storage. The book was created by participants of the International Conference on Electrochemical Materials and Technologies for Clean Sustainable Energy (ICES-2013) held in Guangzhou, China, and incorporates select papers presented at the conference. More than 300 attendees from across the globe participated in ICES-2013 and gave presentations in six major themes: Fuel cells and hydrogen energy Lithium batteries and advanced secondary batteries Green energy for a clean environment Photo-Electrocatalysis Supercapacitors Electrochemical clean energy applications and markets Comprised of eight sections, this book includes 25 chapters featuring highlights from the conference and covering every facet of synthesis, characterization, and performance evaluation of the advanced materials for electrochemical energy. It thoroughly describes electrochemical energy conversion and storage technologies such as batteries, fuel cells, supercapacitors, hydrogen generation, and their associated materials. The book contains a number of topics that include electrochemical processes, materials, components, assembly and manufacturing, and degradation mechanisms. It also addresses challenges related to cost and performance, provides varying perspectives, and emphasizes existing and emerging solutions. The result of a conference encouraging enhanced research collaboration among members of the electrochemical energy community, Electrochemical Energy: Advanced Materials and Technologies is dedicated to the development of advanced materials and technologies for electrochemical energy conversion and storage and details the technologies, current achievements, and future directions in the field.
Sustainable development is a very prevalent concept of modern society. This concept has appeared as a critical force in combining a special focus on development and growth by maintaining a balance of using human resources and the ecosystem in which we are living. The development of new and advanced materials is one of the powerful examples in establishing this concept. Green and sustainable advanced materials are the newly synthesized material or existing modified material having superior and special properties. These fulfil today’s growing demand for equipment, machines and devices with better quality for an extensive range of applications in various sectors such as paper, biomedical, textile, and much more. Volume 2, provides chapters on the valorization of green and sustainable advanced materials from a biomedical perspective as well as the applications in textile technology, optoelectronics, energy materials systems, and the food and agriculture industry.
The impending energy crisis brought on by the running out of finite and non-homogenously distributed fossil fuel reserves and the worldwide increase in energy demand has prompted vast research in the development of sustainable energy technologies in the last few decades. However, the efficiency of most of these new technologies is relatively small and therefore it needs to be increased to eventually replace conventional technologies based on fossil fuels. The required efficiency increase primarily relies on the ability to improve the performance of the functional materials which are at the heart of these technologies. The purpose of this book is to give a unified and comprehensive presentation of the fundamentals and the use and design of novel materials for efficient sustainable energy applications, such as conversion, storage, transmission, and consumption. The book presents general coverage of the use and design of advanced materials for sustainable energy applications. Thus, the book addresses all the relevant aspects, such as materials for energy conversion, storage, transmission, and consumption.